Description of Itmat Expertise

Our laboratory focuses on the DNA modifying enzymes and pathways that provided an added layer of complexity to the genome. These enzymes can be involved in the purposeful introduction of mutations or in the chemical modification of nucleobases, making life's DNA blueprint into a remarkably dynamic entity. Many of these processes are at the heart of the battle between the immune system and pathogens.

We utilize a broad array of approaches, including biochemical characterization of enzyme mechanisms, chemical synthesis of enzyme probes, and biological assays spanning immunology and virology to study DNA modifying enzymes.

Our research program aims to understand, harness and perturb there diversity generating pathways.

Description of Other Expertise

Pharmacology; Drug Discovery

Description of Research Expertise

Our laboratory broadly focuses on DNA modifying enzymes and pathways, particularly those that contribute to genomic plasticity. We utilize a broad array of approaches, including biochemical characterization of enzyme mechanisms, chemical synthesis of enzyme probes, and biological assays spanning immunology and virology to study the fundamental question of how a genomic diversity arises in nature.

Mutation and modification of the genome play an important role in several physiologically relevant areas and our areas of interest include:

From the host immune perspective, the generation of genomic diversity is used as both a defensive and an offensive weapon. Host mutator enzymes such as Activation-Induced Cytidine Deaminase (AID) seed diversity in the adaptive immune system by introducing targeted mutations into the immunoglobulin locus that result in antibody maturation. Related deaminases of the innate immune system can directly attack retroviral threats by garbling the pathogen genome through mutation, as accomplished by the deaminase APOBEC3G, which restricts infection with HIV. Immune mutator enzymes, however, also pose a risk to the host, as overexpression or dysregulation have been associated with oncogenesis.

The singular genome is responsible for a wealth of different cell types, each of which can respond and adapt to environmental cues. In part, these epigenetic differences are linked to DNA modification. These modifications center around cytosine, where DNA deamination (AID/APOBEC enzymes) , oxidation (TET family enzymes) and methylation (DNMTs) can all interplay and tune the genome's potential. We are interested in the enzymatic activities of these cytosine modifying enzymes, particularly in the process of DNA demethylation which plays a role in embryogenesis, gene regulation and a potential pathological role in cancer.

3. Target pathogen pathways that promote evolution and resistance.

From the pathogen perspective, alteration in key antigenic determinants at a rate that outpaces immune responses is a potent means for evasion. Further, rapid mutation may allow for the development of resistance to antimicrobials. In bacteria, adaptation and evolution are closely linked to the stress response of SOS pathway. The SOS pathway can be triggered by numerous stressors, including antibiotics, and the net result is accelerated acquisition of drug resistance. We aim to characterize the key regulatory and effector enzymes from the SOS pathway and to target the pathway as a means to combat antibiotic resistance.

Our research program aims to understand these pathways of purposeful DNA modification and mutation. Additionally, we apply chemical biology to decipher and target these pathways, to impede the development of multidrug-resistance in pathogens or prevent the neoplastic transformations that can result from genomic mutation.